FR3071074A1 - INTEGRATED PHOTONIC INTERCONNECTION SWITCH AND INTEGRATED PHOTONIC INTERCONNECTION NETWORK - Google Patents

Abstract

A photonic interconnection switch integrated in an optoelectronic chip, comprising first and second linear optical waveguides (2, 3) intersecting at an intersection (4) and having first and second ends respectively (a). , b) and third and fourth ends (c, d), and a first and a second redirecting photonic annular resonators (5, 6), coupled together in an intermediate optical coupling region (9) and controllable by a signal electrical, and wherein the first annular resonator (5) is coupled to the first optical waveguide (2) at a first optical coupling area (10) on the side of said first end (a), and the second annular resonator (6) is coupled to the second optical waveguide (3) in a second optical coupling region (11) located on the side of said third end (c). Non-blocking photonic interconnection network including multiple switches.

Description

Integrated photon interconnect switch and integrated photon interconnect network

According to embodiments, the present invention relates to the field of photonic interconnection switches integrated in optoelectronic chips and photonic interconnection networks integrated in optoelectronic chips and including such switches.

It is known to produce linear optical waveguides, integrated in optoelectronic chips and capable of confining and guiding light.

It is also known to make photonic interconnection switches integrated in optoelectronic chips, making it possible to transfer photons from one optical waveguide to another optical waveguide via an annular redirection resonator , controllable by an electrical signal.

Generally, the resonator comprises an integrated ring and an integrated electronic component adjacent to this ring and controllable by an electrical signal, the integrated ring having portions adjacent to the optical waveguides so as to form zones of optical coupling between the ring and optical waveguides.

In the absence of an electrical signal, the integrated ring is in a state called "non-resonant" such as a light wave, brought to a coupling zone by an optical waveguide, crosses this coupling zone and continues its path in this optical waveguide.

On the other hand, in the presence of an electrical signal, the integrated electronic component modifies the state of the integrated ring which is then placed in a so-called "resonant" state such as a light wave which reaches a coupling zone by l one of the optical waveguides is transferred to the integrated ring and then transferred to the other optical waveguide via the other coupling zone, the light wave continuing its path in the other waveguide optics in an opposite direction.

Commonly, the structures described above are produced on silicon and silicon on insulator (SOI) substrates.

Furthermore, the document IEEE TRANSACTIONS ON COMPUTERS VOL. 65 NO 6 JUNE 2016 offers complex photonic interconnection networks integrated in optoelectronic chips, which include a plurality of optical waveguides and a plurality of switches, as described above, and which include intersections between the guides optical waves, for the selective transfer of data and data packets between sources and recipients, by selectively controlling the resonators.

The photon interconnection networks described above are limited by the losses and crosstalk which degrade the signals transmitted when the optical waves pass through intersections or resonators. They should therefore be limited to the maximum.

A photonic interconnection switch integrated in an optoelectronic chip is proposed, which comprises first and second linear optical waveguides, which intersect by forming an intersection and which have first and second ends and third and fourth ends respectively. extremities; and a first and a second annular photonic redirection resonators, coupled together in an intermediate optical coupling zone and controllable by an electrical signal.

In addition, the first annular resonator is coupled to the first optical waveguide in a first optical coupling region located on the side of said first end and the second annular resonator is coupled to the second optical waveguide in a second coupling region. optical located on the side of said third end.

Advantageously, the switch can have an axis of symmetry passing through said intersection and said intermediate coupling zone between said annular resonators.

The first and second optical waveguides may include first parallel portions coupled to said resonators and second cross portions intersecting in forming said intersection.

Furthermore, a photonic interconnection network integrated in an optoelectronic chip is proposed, which comprises at least one photonic interconnection switch as defined above.

Furthermore, a photonic interconnection network integrated in an optoelectronic chip is also proposed, which comprises a first group of four switches as defined above and a second group of four switches as defined above.

In the first group of switches, connections are made as follows.

A link connects the second end of a first switch and the first end of a second switch, so that the first optical waveguides of the first and second switches are in series.

A link connects the fourth end of the first switch and the third end of a third switch, so that the second optical waveguides of the first and third switches are in series.

A link connects the fourth end of the second switch and the third end of a fourth switch, so that the second optical waveguides of the second and fourth switches are in series.

A link connects the second end of the third switch and the first end of the fourth switch, so that the first optical waveguides of the third and fourth switches are in series.

In a second group of switches the connections are made as follows.

A link connects the second end of a fifth switch and the first end of a sixth switch, so that the first optical waveguides of the fifth and sixth switches are in series.

A link connects the fourth end of the fifth switch and the third end of a seventh switch, so that the second optical waveguides of the fifth and seventh switches are in series.

A link connects the fourth end of the sixth switch and the third end of an eighth switch, so that the second optical waveguides of the sixth and eighth switches are in series.

A link connects the second end of the seventh switch and the first end of the eighth switch, so that the first optical waveguides of the third and fourth switches are in series.

Furthermore, said network with two groups of switches comprises: a link between the third end of the first switch and the first connection of the fifth switch, a link between the third end of the second switch and the first end of the seventh switch, a link between the second end of the second switch and the fourth end of the seventh switch, and a link between the second end of the fourth switch and the fourth end of the eighth switch.

Advantageously, said network with two switch groups can have the following arrangements.

The first ends of the first and third switches can be connected to external links.

The fourth ends of the third and fourth switches can be connected to external links.

The third ends of the fifth and sixth switches can be connected to external connections.

The second ends of the sixth and eighth switches can be connected to external links.

The first group of switches may have an axis of symmetry passing through the intersections of the optical waveguides of the first and fourth switches, the second and third switches being on either side of this axis of symmetry.

The second group of switches may have an axis of symmetry passing through the intersections of the optical waveguides of the fifth and eighth switches, the sixth and seventh switches being on either side of this axis of symmetry.

The first group of switches and the second group of switches can be made on either side of an axis of symmetry, the second and the seventh switches being on the side of this axis of symmetry.

Said external links connected to the first and fifth switches can cross by forming an intersection and said external links connected to the fourth and eighth switches can cross by forming an intersection.

Said external links connected to the third and fifth switches, said external links connected to the first and sixth switches, said external links connected to the third and eighth switches and said external links connected to the fourth and sixth switches may be respectively connected to devices having connections of transmission and reception of optical waves.

A photonic interconnection switch, integrated into an electronic chip, and a photonic interconnection network, integrated into an electronic chip, including switches will now be described by way of nonlimiting examples, illustrated by the drawing in which:

FIG. 1 represents a plan view of an integrated photonic interconnection switch;

FIG. 2 represents a plan view of an integrated photonic interconnection network including eight switches; and

FIGS. 3A-C, 4A-C, 5A-C and 6A-C represent modes of circulation of optical waves in the network of FIG. 2.

In FIG. 1 is illustrated a photonic interconnection switch 1, integrated in an optoelectronic chip.

The switch 1 comprises, in the same plane, a first and a second linear guide of optical waves 2 and 3 which cross by forming an intersection 4 and which have first and second ends a and b respectively and third and fourth ends ç and d.

Switch 1 includes first and second annular photonic redirection resonators 5 and 6, controllable by an electrical signal.

The photonic redirectional resonators 5 and 6 include rings 7 and 8 forming optical waveguides. The rings 7 and 8 are made in the same plane as the optical waveguides 2 and 3, between the optical waveguides 2 and 3 and on the side of the ends a and ç.

The rings 7 and 8 are adjacent so as to form between them a local intermediate optical coupling zone 9. The ring 7 is adjacent to the optical waveguide 2 so as to form between them a first optical coupling zone 10. L the ring 8 is adjacent to the optical waveguide 3 so as to form between them a second local optical coupling zone 11. The local optical coupling zones 9, 10 and 11 form so-called "evanescent" optical couplings.

The rings 7 and 8 are associated with integrated components (not shown), which, when subjected to an electrical signal, are capable of modifying the state of the annular resonators 5 and 6.

The switch 1 advantageously has, for reasons of ease of manufacture, a longitudinal geometric axis of symmetry 12 passing through the intersection 4 and through the intermediate coupling zone 9 between the annular resonators 5 and 6.

According to a particular arrangement illustrated in FIG. 1, the optical waveguides 2 and 3 comprise rectilinear portions 2a and 3a and parallel to the axis of symmetry 12, between which are placed the rings 7 and 8 of the annular resonators 5 and 6, and rectilinear portions 2b and 3b which intersect by forming the intersection 4 and which are oriented at 45 ° relative to the axis of symmetry 12 by forming a cross. The centers of the rings 7 and 8 are placed on a line which is perpendicular to the rectilinear portions 2a and 3a of the optical waveguides 2 and 3.

Switch 1 operates as follows.

In the absence of an electrical activation signal from the resonators 5 and 6, the rings 7 and 8 are in an "OFF" state (non-resonant). A light wave entering through one end of the optical waveguide 2 exits through the other end of the optical waveguide 2 passing through the intersection 4 and a light wave entering through one of the ends of the guide of optical waves 3 comes out directly from the other end of the optical waveguide 3 passing through intersection 4.

In the presence of an electrical signal activating said associated integrated electronic components of the resonators 5 and 6, the rings 7 and 8 of the resonators 5 and 6 are in an "ON" (resonant) state. The following redirects occur.

A light wave entering through the end a of the optical waveguide 2, when it reaches the coupling zone 10, is redirected towards the optical waveguide 3 via successively the rings 7 and 8. Then, the wave light is directed towards the end d of the optical waveguide 3 passing through the intersection 4.

A light wave entering through the end ç of the optical waveguide 3, when it reaches the coupling zone 11, is redirected towards the optical waveguide 2 via successively the rings 8 and 7. Then, the wave light is directed towards the end b of the optical waveguide 2 passing through the intersection 4.

A light wave entering via the end b of the optical waveguide 2, when it reaches the coupling zone 10 after having crossed the intersection 4, is redirected towards the optical waveguide 3 via successively the rings 7 and 8. Then, the light wave is directed towards the end ç of the optical waveguide 3.

A light wave entering through the end d of the optical waveguide 3, when it reaches the coupling zone 11 after passing through the intersection 4, is redirected towards the optical waveguide 2 via successively the rings 8 and 7. Then, the light wave is directed towards the end a of the optical waveguide 2.

It follows that any incoming light wave crosses the intersection 4, that it flows directly from one end to the other of the optical waveguides 2 and 3 or that it is redirected from one of the optical waves 2 and 3 to each other.

Each resonator has a classic form called "Lorentzian" of its resonance versus frequency (or wavelength). Switch 1, on the other hand, has a higher-order form of resonance which makes it possible both to better reject spurious signals of different wavelengths, and to guarantee maximum transmission for wavelengths close to resonance, in order to preserve the spectral density of the modulated signal and therefore its temporal form.

In FIG. 2 is illustrated a photonic interconnection network 100 integrated in an optoelectronic chip, which is intended to selectively make photonic connections between four electronic devices 101, 102, 103 and 104 which respectively have optical connections.

The network 100 comprises a first group 105 of four switches C1, C2, C3 and C4 and a second group 106 of four switches C5, C6, C7 and C8. These eight switches each correspond to switch 1 described above with reference to FIG. 1, the optical waveguides 2 and 3 and the rings 7 and 8 being produced in the same plane.

The eight switches are arranged so that their axes of symmetry 12 are parallel to a longitudinal geometric main axis of symmetry 107, going from right to left in FIG. 2, and that their intersections 4 are on the same side with respect to the rings 7 and 8, on the left side in Figure 2.

The groups 105 and 106 are arranged symmetrically on either side of the main axis of symmetry 107.

The switches C1, C2, C3 and C4 of the first group 105 are arranged symmetrically with respect to a secondary axis of symmetry 108 which is parallel to the main axis of symmetry 107, being arranged in the regions of the vertices of a diamond. The axes of symmetry 12 of switches C1 and C4 are on the secondary axis of symmetry 108. The switches Cl and C4 are offset longitudinally, the switch Cl being on the right in FIG. 2 and the switch C4 being on the left. The switches C2 and C3 are on either side of the secondary axis of symmetry 108, the switch C2 being on the side of the main axis of symmetry 107.

The portions 3a of the second guides 3 of the switches C1, C2, C3 and C4 are on the side of the main axis of symmetry 107 with respect to the portions 2a of the first optical waveguides 2, so that the ends ç and b are on the side of the main axis of symmetry 107 with respect to the ends a and d.

The switches C5, C6, C7 and C8 of the second group 106 are arranged symmetrically with respect to a secondary axis of symmetry 109 which is parallel to the main axis of symmetry 107, being arranged in the areas of the vertices of a diamond. The axes of symmetry 12 of the switches C5 and C8 are on the secondary axis of symmetry 108. The switches C5 and C8 are offset longitudinally, the switch C5 being on the right in FIG. 2 and the switch C8 being on the left. The switches C6 and C7 are on either side of the secondary axis of symmetry 109 the switch C7 being on the side of the main axis of symmetry 107.

The portions 2a of the first guides 2 of the switches C5, C6, C7 and C8 are on the side of the main axis of symmetry 107 with respect to the portions 3a of the second optical waveguides 3, so that the ends a and d are on the side of the main axis of symmetry 107 with respect to the ends ç and b.

The centers of rings 7 and 8 of switches C1 and C5 are on the same line perpendicular to the main axis of symmetry 107.

The intersections 4 of switches C1 and C7 are on the same line perpendicular to the main axis of symmetry 107.

The centers of the rings 7 and 8 of the switches C2, C3, C6 and C7 are on the same line perpendicular to the main axis of symmetry 107.

The intersections 4 of the switches C2, C3, C6 and C7 are on the same line perpendicular to the main axis of symmetry 107.

The centers of rings 7 and 8 of switches C4 and C8 are on the same line perpendicular to the main axis of symmetry 107.

The intersections 4 of the switches C4 and C8 are on the same line perpendicular to the main axis of symmetry 107.

The electronic device 101 is on the side of the switch C1, on the right in FIG. 1.

The electronic device 102 is on the side of the switch C4, on the left in FIG. 1.

The electronic device 103 is on the side of the switch C5, on the right in FIG. 1. The electronic device 104 is on the side of the switch C8, on the right in FIG. 1.

Optical connections, in the form of portions of optical waveguides, are made in the following manner.

A link 110 connects the end b of the first optical waveguide of the switch C1 to the end a of the first optical waveguide of the switch C2, so that the first optical waveguides of the switches C1 and C2 are serial.

A link 111 connects the end d of the second optical waveguide of the switch C1 to the ç end of the second optical waveguide of the switch C3, so that the second optical waveguides of the switches C1 and C3 are serial.

A link 112 connects the end d of the second optical waveguide of the switch C2 to the ç end of the second optical waveguide of the switch C4, so that the second optical waveguides of the switches C2 and C4 are serial.

A link 113 connects the end b of the first optical waveguide of the switch C3 to the end a of the first optical waveguide of the switch C4, so that the first optical waveguides of the switches C3 and C4 are serial.

A link 114 connects the end b of the first optical waveguide of the switch C5 to the end a of the first optical waveguide of the switch C6, so that the first optical waveguides of the switches C5 and C6 are serial.

A link 115 connects the end d of the second optical waveguide of the switch C5 to the end ç of the second optical waveguide of the switch C7, so that the second optical waveguides of the switches C5 and C7 are serial.

A link 116 connects the end d of the second optical waveguide of the switch C6 to the end ç of the second optical waveguide of the switch C8, so that the second optical waveguides of the switches C6 and C8 are serial.

A link 117 connects the end ~ b of the first optical waveguide of the switch C7 to the end a of the first optical waveguide of the switch C8, so that the first optical waveguides of the switches C7 and C8 are in series.

A link 118, which crosses the main axis of symmetry 107, connects the end ç of the second optical waveguide of switch C1 to the end a of the first optical waveguide of switch C5, so that the second optical waveguide of switch C1 and the first optical waveguide of switch C5 are in series.

A link 119, which crosses the main axis of symmetry 107, connects the end ç of the second optical waveguide of the switch C2 to the end a of the first optical waveguide of the switch C7, so that the second switch C2 optical waveguide and the first switch C7 optical waveguide are in series.

A link 120, which crosses the main axis of symmetry 107, connects the end b of the first optical waveguide of the switch C2 to the end d of the second optical waveguide of the switch C7, so that the first switch C2 optical waveguide and the second switch C7 optical waveguide are in series.

A link 121, which crosses the main axis of symmetry 107, connects the end b of the first optical waveguide of the switch C4 to the end d of the second optical waveguide of the switch C8, so that the first optical waveguide of switch C4 and the second optical waveguide of switch C8 are in series.

The a end of the first optical waveguide of the switch C1, the a end of the first optical waveguide of the switch C3,

the end vs of second guide wave optical of switch C5 the end vs of second guide wave optical of switch C6 the end d of second guide wave optical of switch C3, the end d of second guide wave optical of switch C4 the end b of first guide wave optical of switch C6 the end b of second guide wave optical of switch C8

constitute external connections of the network 1.

It follows from the arrangements described above that the network 1 contains no other intersection than the intersections 4 of the switches C1 to C8.

We will now describe a particular mode of connection of the external connections of the network 1, mentioned above, to the devices 101 to 104, which each comprise two optical connections.

A link 122 connects the end a of the first optical waveguide of the switch C3 to a connection 101a of the device 101, so that the first optical waveguide of the switch C3 and the connection 101a are in series.

A link 123 connects the end d of the second optical waveguide of the switch C3 to a connection 102b of the device 102, so that the second optical waveguide of the switch C3 and the connection 102b are in series.

A link 124 connects the end ç of the second optical waveguide of the switch C6 to a connection 103b of the device 103, so that the second optical waveguide of the switch C6 and the connection 103b are in series.

A link 125 connects the end b of the first optical waveguide of the switch C6 to a connection 104a of the device 104, so that the first optical waveguide of the switch C6 and the connection 104a are in series.

A link 126, which crosses the main axis of symmetry 107, connects the end a of the first optical waveguide of the switch C1 to a connection 103a of the device 103, so that the first optical waveguide of the switch Cl and connection 103a are in series.

A link 127, which crosses the main axis of symmetry 107, connects the end ç of the second optical waveguide of switch C5 to a connection 101b of device 101, so that the second optical waveguide of switch C5 and connection 101b are in series.

Links 126 and 127 intersect, forming an intersection 128, the center of which is located on the main axis of symmetry 107.

A link 129, which crosses the main axis of symmetry 107, connects the end d of the second optical waveguide of the switch C4 to a connection 104b of the device 104, so that the second optical waveguide of the switch C4 and connection 104b are in series.

A link 130, which crosses the main axis of symmetry 107, connects the end b of the first optical waveguide of the switch C8 to a connection 102a of the device 102, so that the first optical waveguide of the switch C8 and connection 102a are in series.

The links 129 and 130 intersect, forming an intersection 131, the center of which is located on the main axis of symmetry 107.

Thus, only the complementary intersections 128 and 131 are added to the intersections 4 of the switches C1 to C8.

Considering that one of the connections of devices 101, 102, 103 and 104 is an input and the other an output, a special arrangement may be as follows. However, a reverse arrangement could be adopted.

On the one hand, the connection 101a of the device 101, the connection 102a of the device 102, the connection 103a of the device 103 and the connection 104a of the device 104 are connections emitting optical waves. Thus, in correspondence and respectively, the links 122, 130, 126 and 125 constitute optical wave inputs in the network 100.

On the other hand, connection 101b of device 101, connection 102a of device 102, connection 103b of device 103, connection 101b of device 101 and connection 104b of device 104 are optical wave receiving connections. Thus, in correspondence and respectively, the links 127, 123, 124 and 129 constitute optical wave outputs from the network 100.

Considering that each of the devices 101 to 104 is such that it cannot receive, at a given instant, light waves coming from only one device other than itself, the following modes of circulation or optical paths can be produced by selectively activating the resonators 5 and 6 of switches C1 to C8.

In FIG. 3A is illustrated the case where an optical wave is emitted on the emitting connection 101a of the device 101 and is intended for the receiving connection 103b of the device 103. The emitted optical wave circulates in the link 122, then in the first guide of optical waves of switch C3, then in the first optical waveguide of switch C4, then in link 121, then in the second optical waveguide of switch C8, then in the second optical waveguide of switch C6 and finally in link 124.

In FIG. 3B is illustrated the case where an optical wave is emitted on the emitting connection 101a of the device 101 and is intended for the receiving connection 102b of the device 102, by activating the resonators of the switch C3. The transmitted optical wave circulates in the link 122, then is diverted in the switch C3 from its first optical waveguide to its second optical waveguide, and finally circulates in the link 123.

In FIG. 3C is illustrated the case where an optical wave is emitted on the emitting connection 101a of the device 101 and is intended for the receiving connection 104b of the device 103, by activating the resonators of the switch C4. The optical wave emitted circulates in the link 122, then in the first optical waveguide of the switch C3, then is derived in the switch C4 from its first optical waveguide to its second optical waveguide, and finally runs on link 129.

In FIG. 4A is illustrated the case where an optical wave is emitted on the emitting connection 102a of the device 102 and is intended for the receiving connection 104b of the device 104. The emitted optical wave circulates in the link 130, then in the first guide of optical waves of switch C8, then in the first optical waveguide of switch C7, then in link 119, then in the second optical waveguide of switch C2, then in the second optical waveguide of switch C4 and finally in link 129.

In FIG. 4B is illustrated the case where an optical wave is emitted on the emitting connection 102a of the device 102 and is intended for the receiving connection 103b of the device 103, by activating the resonators of the switch C8. The transmitted optical wave circulates in the link 130, then is diverted in the switch C8 from its first optical waveguide to its second optical waveguide, then circulates in the second optical waveguide of the switch C6 and finally in link 124.

In FIG. 4C is illustrated the case where an optical wave is emitted on the emitting connection 102a of the device 102 and is intended for the receiving connection 101b of the device 101, by activating the resonators of the switch C7. The optical wave emitted circulates in the link 130, then in the first optical waveguide of the switch C8, then is diverted in the switch C7 from its first optical waveguide to its second optical waveguide, then circulates in the second optical waveguide of switch C5 and finally in link 127.

In FIG. 5A is illustrated the case where an optical wave is emitted on the emitting connection 103a of the device 103 and is intended for the receiving connection 101b of the device 101. The emitted optical wave circulates in the link 126, then in the first guide of optical waves of switch C1, then in the first optical waveguide of switch C2, then in link 120, then in the second optical waveguide of switch C7, then in the second optical waveguide of switch C5 and finally in link 127.

FIG. 5B illustrates the case where an optical wave is emitted on the emitting connection 103a of the device 103 and is intended for the receiving connection 102b of the device 102, by activating the resonators of the switch C1. The emitted optical wave circulates in the link 126, then is derived in switch C1 from its first optical waveguide to its second optical waveguide, then flows through the second optical waveguide of switch C3 and flows through link 123.

In FIG. 5C is illustrated the case where an optical wave is emitted on the emitting connection 103a of the device 103 and is intended for the receiving connection 104b of the device 104, by activating the resonators of the switch C2. The transmitted optical wave circulates in the link 126, then in the first optical waveguide of the switch C1, then is diverted in the switch C2 from its first optical waveguide to its second optical waveguide, then circulates in the second optical waveguide of switch C4 and finally in link 129.

In FIG. 6A is illustrated the case where an optical wave is emitted on the emitting connection 104a of the device 104 and is intended for the receiving connection 102b of the device 102. The emitted optical wave circulates in the link 125, then in the first guide of optical waves of switch C6, then in the first optical waveguide of switch C5, then in link 119, then in the second optical waveguide of switch C1, then in the second optical waveguide of switch switch C3 and finally in link 123.

In FIG. 6B is illustrated the case where an optical wave is emitted on the emitting connection 104a of the device 104 and is intended for the receiving connection 103b of the device 103, by activating the resonators of the switch C6. The transmitted optical wave circulates in the link 125, then is diverted in the switch C6 from its first optical waveguide to its second optical waveguide, then circulates in the link 124.

In FIG. 6C is illustrated the case where an optical wave is emitted on the emitting connection 104a of the device 104 and is intended for the receiving connection 101b of the device 101, by activating the resonators of the switch C5. The transmitted optical wave circulates in the link 125, then in the first optical waveguide of the switch C6, then is diverted in the switch C5 from its first optical waveguide to its second optical waveguide, then circulates in link 127.

When the devices 101 and 102 communicate with each other (Figures 3B and 4C), the devices 103 and 104 can communicate with each other without interfering with the previous ones (Figures 5C and 6B).

When the devices 101 and 103 communicate with each other (Figures 3A and 5A), the devices 102 and 104 can communicate with each other without interfering with the previous ones (Figures 4A and 6A).

When the devices 101 and 104 communicate with each other (Figures 3C and 6C), the devices 102 and 103 can communicate with each other without interfering with the previous ones (Figures 4B and 5B).

When the devices 102 and 103 communicate with each other (Figures 4B and 5B), the devices 101 and 104 can communicate with each other without interfering with the previous ones (Figures 3C and 6C).

When the devices 102 and 104 communicate with each other (Figures 4A and 6A), the devices 101 and 103 can communicate with each other without interfering with the previous ones (Figures 3C and 5A).

It follows from the above that any device 101 to 104 can freely transmit information to any other device by simply respecting the fact that a device can only receive (respectively transmit) signals from (respectively direction) of only one other device at a time. Consequently, although it includes a reduced number of intersections as indicated above, the network 100 is said to be “non-blocking”.

Claims (11)

1. Photonic interconnection switch integrated in an optoelectronic chip, comprising first and second linear optical waveguides (2, 3), which intersect forming an intersection (4) and which have first and second ends respectively (a, b) and third and fourth ends (c, d), and first and second annular photonic redirection resonators (5, 6), coupled together in an intermediate optical coupling zone (9) and controllable by an electrical signal, and in which the first annular resonator (5) is coupled to the first optical waveguide (2) in a first optical coupling zone (10) located on the side of said first end (a), and the second annular resonator (6) is coupled to the second optical waveguide (3) in a second optical coupling zone (11) located on the side of said third end (c). 2. Switch according to claim 1, having an axis of symmetry (12) passing through said intersection (4) and said intermediate coupling zone (9) between said annular resonators. 3. Switch according to one of claims 1 and 2, wherein the first and second optical waveguides comprise first parallel portions (2a, 3a) coupled to said resonators and second cross portions (2b, 3b) crossing by forming said intersection (4). 4. Photonic interconnection network integrated in an optoelectronic chip, comprising at least one photonic interconnection switch according to any one of the preceding claims. 5. Photonic interconnection network integrated in an optoelectronic chip, comprising: - A first group (105) of four switches (C1-C4) according to any one of claims 1 to 3, in which a link (110) connects the second end (b) of a first switch (Cl) and the first end (a) of a second switch (C2), so that the first optical waveguides of the first and second switches (C1, C2) are in series, a link (111) connects the fourth end (d ) of the first switch (Cl) and the third end (c) of a third switch (C3), so that the second optical waveguides of the first and third switches (Cl, C3) are in series, a link (112) connects the fourth end (d) of the second switch (C2) and the third end (c) of a fourth switch (C4), so that the second optical waveguides of the second and fourth switches (C2 , C4) are in series, a link (113) connects the second end (b) of the third switch (C3) and the first end (a) of the fourth switch (C4), so that the first optical waveguides of the third and fourth switches (C3, C4) are in series, - and a second group (106) of four switches (C5-C8) according to any one of claims 1 to 4, in which a link (114) connects the second end (b) of a fifth switch (C5) and the first end (a) of a sixth switch (C6), so that the first optical waveguides of the fifth and sixth switches (C5, C6) are in series, a link (115) connects the fourth end ( d) of the fifth switch (C5) and the third end (c) of a seventh switch (C7), so that the second optical waveguides of the fifth and seventh switches (C5, C7) are in series, one link (116) connects the fourth end (d) of the sixth switch (C6) and the third end (c) of an eighth switch (C8), so that the second optical waveguides of the sixth and eighth switches ( C6, C8) are in series, a link (117) connects the second end (b) of the seventh switch (C7) and the first end (a) of the eighth switch (C8), so that the first optical waveguides of the third and fourth switches (C3, C4) are in series, and comprising: a link (118) between the third end (c) of the first switch (Cl) and the first connection (a) of the fifth switch (C5), a link (119) between the third end (c) of the second switch (C2) and the first end (a) of the seventh switch (C7), a link (120) between the second end (b) of the second switch (C2) and the fourth end (d) of the seventh switch (C7), a link (121 ) between the second end (c) of the fourth switch (C4) and the fourth end (d) of the eighth switch (C8). 6. Network according to claim 5, in which: the first ends (a) of the first and third switches (C1, C3) are connected to external links (122, 126), the fourth ends (d) of the third and fourth switches (C3, C4) are connected to external connections (123, 129), the third ends (c) of the fifth and sixth switches (C3, C6) are connected to external connections (124, 127), the second ends (b) of the sixth and eighth switches (C6, C8) are connected to external links (125, 130). 7. Network according to one of claims 5 and 6, in which: the first group (105) of switches has an axis of symmetry (108) passing through the intersections (4) of the optical waveguides of the first and fourth switches (C1, C4), the second and third switches (C2, C3) being on either side of this axis of symmetry. 8. Network according to any one of the preceding claims 5 to 7, in which: the second group (105) of switches has an axis of symmetry (109) passing through the intersections (4) of the optical waveguides of the fifth and eighth switches (C5, C8), the sixth and seventh switches (C6, C7) being on either side of this axis of symmetry. 9. Network according to any one of the preceding claims 5 to 8, in which: the first group (105) of switches and the second group (106) of switches are made on either side of an axis of symmetry (107), the second and the seventh switches (C2, C7) being on the side of this axis of symmetry. 10. Network according to any one of the preceding claims 5 to 9, in which: 5 said external links (126, 127) connected to the first and fifth switches (Cl, C5) intersect forming an intersection (128) and said external links (129, 130) connected to the fourth and eighth switches (C4, C8 ) intersect by forming an intersection (131). 10 11. Network according to claim 10, in which: said external links (122, 127) connected to the third and fifth switches (C3, C5), said external links (124, 126) connected to the first and sixth switches (C1, C6), said external links (123, 130) connected to the third and eighth switches (C3, 15 C8) and said external links (125, 129) connected to the fourth and sixth switches (C4, C6) are respectively connected to devices (101, 103, 102, 104) having connections d transmission and reception of optical waves.